Control circuit for controlling reset operation

ABSTRACT

A control circuit includes a reset circuit and a determination circuit. The reset circuit is coupled to a digital frequency divider of a phase locked loop circuit and configured to perform a reset operation. The determination circuit is coupled to the reset circuit and configured to determine whether a first predetermined time interval has elapsed so as to control the reset circuit to stop performing the reset operation when the first predetermined time interval has elapsed.

CROSS REFERENCE TO RELATED APPLICATION

This application is a division of U.S. application Ser. No. 15/878,363filed Jan. 23, 2018, which is included herein by reference in itsentirety.

TECHNICAL FIELD

The present invention is related to a control circuit capable ofcontrolling a reset operation according to whether a predetermined timeinterval has elapsed.

BACKGROUND

When operating a functional circuit, it requires excessive setting timefor the functional circuit to stabilize, and this has been a problem tobe solved in the field. FIG. 1 illustrates an output voltage-time curveof a functional circuit according to prior art. In FIG. 1, thefunctional circuit may be a phase locked loop circuit as an example. Thehorizontal axis is time, and the vertical axis refers to an outputvoltage of a phase locked loop circuit. As shown in FIG. 1, when thefunctional circuit is initialized, the output voltage is unstable duringa time interval T11. The output voltage is unstable because the negativefeedback mechanism of the functional circuit has not yet stabilized.

As shown in FIG. 1, after the time interval T11 has elapsed, it stillrequires a time interval T12 for the output voltage to stabilize. Thusthe setting time to stabilize the output voltage is at least a sum ofthe time intervals T11 and T12. This makes the functional circuit highlyinefficient. Hence, a solution is required for solving a problem of thatthe setting time is excessive.

SUMMARY

An embodiment provides a control circuit including a reset circuit and adetermination circuit. The reset circuit is coupled to a digitalfrequency divider of a phase locked loop circuit and configured toperform a reset operation. The determination circuit is coupled to thereset circuit and configured to determine whether a first predeterminedtime interval has elapsed so as to control the reset circuit to stopperforming the reset operation when the first predetermined timeinterval has elapsed.

Another embodiment provides a control circuit including a reset circuitand a determination circuit. The reset circuit is coupled to a digitalcircuit of a functional circuit and configured to perform a resetoperation to the digital circuit. The determination circuit is coupledto the reset circuit and configured to determine whether a firstpredetermined time interval has elapsed so as to control the resetcircuit to stop performing the reset operation when the firstpredetermined time interval has elapsed. The functional circuit includesan analog circuit and a digital circuit coupled to the analog circuit.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an output voltage-time curve of a functional circuitaccording to prior art.

FIG. 2 illustrates application of a control circuit according to anembodiment.

FIG. 3 illustrates a signal waveform diagram of the reset circuit ofFIG. 2 according to an embodiment.

FIG. 4 illustrates a signal waveform diagram of the reset circuit ofFIG. 2 according to another embodiment.

FIG. 5 illustrates a signal waveform diagram of the reset circuit ofFIG. 2 according to another embodiment.

FIG. 6 illustrates application of a control circuit according to anotherembodiment.

FIG. 7 illustrates application of a control circuit according to anotherembodiment.

FIG. 8 illustrates a partial circuit of the control circuit of FIG. 7according to another embodiment.

FIG. 9 illustrates application of a control circuit according to anotherembodiment.

FIG. 10 illustrates application of a control circuit according toanother embodiment.

DETAILED DESCRIPTION

Below, exemplary embodiments will be described in detail with referenceto accompanying drawings so as to be easily realized by a person havingordinary knowledge in the art. The inventive concept may be embodied invarious forms without being limited to the exemplary embodiments setforth herein. Descriptions of well-known parts are omitted for clarity,and like reference numerals refer to like elements throughout.

FIG. 2 illustrates application of a control circuit 200 according to anembodiment. The control circuit 200 may include a reset circuit 210 anda determination circuit 220. The reset circuit 210 may be coupled to adigital circuit 22 d of a functional circuit 22 and used to perform areset operation to the digital circuit 22 d. For example, performing thereset operation may be transmitting at least one reset signal Sr toreset the digital circuit 22 d. The determination circuit 220 may becoupled to the reset circuit 210 and used to determine whether apredetermined time interval T1 has elapsed so as to control the resetcircuit 210 to stop performing the reset operation when thepredetermined time interval T1 has elapsed. For example, stoppingperforming the reset operation may be stopping transmitting the at leastone reset signal Sr, or converting the reset signal Sr from an enablinglevel to a disabling level. Converting the reset signal Sr from anenabling level to a disabling level may be converting the reset signalSr from a high level to a low level, or from a low level to a high levelaccording to a reset level of the digital circuit 22 d. As shown in FIG.2, the reset circuit 210 may include an output terminal to perform thereset operation or stop performing the reset operation.

The functional circuit 22 may also include an analog circuit 22 acoupled to the digital circuit 22 d. According an embodiment, thefunctional circuit 22 may be a phase locked loop circuit. The functionalcircuit 22 of FIG. 2 may merely illustrate a partial and simplifieddiagram of the foresaid phase locked loop circuit. The digital circuit22 d may be a digital frequency divider of the phase locked loopcircuit, and the analog circuit 22 a may be an analog frequency dividerof the phase locked loop circuit. The predetermined time interval T1 maycorrespond to a time required for the analog circuit 22 a to stabilize.

FIG. 3 illustrates a signal waveform diagram when the reset circuit 210of FIG. 2 performs the reset operation and stops performing the resetoperation. In the example of FIG. 3, the enabling level of the resetsignal Sr is a high level, and the disabling level of the reset signalSr is a low level. This setting is merely an example instead of limitingthe scope. As shown in FIG. 3, the reset circuit 210 may perform thereset operation during the predetermined time interval T1 to reset thedigital circuit 22 d, and stop performing the reset operation when thepredetermined time interval T1 has elapsed.

For example, if the analog circuit 22 a requires a time interval Ta tostabilize, the predetermined time interval T1 may be set substantiallyequal to or even longer than the time interval Ta for ensuring that thereset circuit 210 may perform or stop performing the reset operationeffectively. This is because that the time interval required by theanalog circuit 22 a to stabilize may vary by external factors such asmanufacturing process and ambient temperature. In the example of FIG. 3,the reset circuit 210 may perform the reset operation (e.g. keepingtransmitting at least one reset signal Sr) to the digital circuit 22 dbefore the analog circuit 22 a stabilizes, and the reset circuit 210 maykeep performing the reset operation for a safety time interval after theanalog circuit 22 a has stabilized before stopping performing the resetoperation. This may avoid the unstable output voltage occurring duringthe time interval T11 in FIG. 1, and alleviate the problem of theexcessive setting time. The foresaid safety time interval may be 10% ofthe time interval Ta or another suitable time interval. It is uselessfor shortening the setting time of the functional circuit 22 to performthe reset operation before the analog circuit 22 a has stabilized (e.g.transmitting the reset signal Sr during the time interval T31). However,it is also useless for shortening the setting time of the functionalcircuit 22 to perform the reset operation after the safety time intervalhas elapsed after the analog circuit 22 a has stabilized (e.g.transmitting the reset signal Sr during the time interval T32). Hence,the predetermined time interval T1 may be substantially longer than timeinterval Ta. The difference of the predetermined time interval T1 andtime interval Ta (i.e. (T1−Ta)) may not be longer than the safety timeinterval for preventing that the desired effect of shortening thesetting time of the functional circuit 22 cannot be obtained. Thus, thereset operation may be performed to the digital circuit 22 d constantlytill the safety time interval has elapsed after the analog circuit hasstabilized, and then the reset operation may be stopped so as tooptimize the shortening of the setting time of the functional circuit22.

FIG. 4 illustrates a signal waveform diagram when the reset circuit 210of FIG. 2 performs the reset operation and stops performing the resetoperation according to another embodiment. FIG. 4 may be compared withFIG. 3. In the embodiment of FIG. 3, transmitting the reset signal Srconstantly during the predetermined time interval T1 is to keep resetsignal Sr at an enabling level (e.g. a high level). In the embodiment ofFIG. 4, transmitting the reset signal Sr constantly during thepredetermined time interval T1 is to transmit the at least one resetsignals Sr each having a pulse waveform continually during thepredetermined time interval T1, and stop performing the reset operationby stopping transmitting the reset signal Sr when the predetermined timeinterval T1 has elapsed. The signal waveform of FIG. 4 may be useful toshorten the setting time of the functional circuit 22.

FIG. 5 illustrates a signal waveform diagram when the reset circuit 210of FIG. 2 performs the reset operation and stops performing the resetoperation according to another embodiment. As mentioned above, a timeinterval between a time point on which the time interval Ta finishes andanother time point on which the predetermined time interval T1 finishesmay be the safety time interval. It may be assured that the analogcircuit 22 a has stabilized, and the digital circuit 22 d may be reseteffectively during the safety time interval. Hence, at least one resetsignal Sr may be transmitted during the time interval T51 to reset thedigital circuit 22 d. After the time interval T51, it may be stopped toreset the digital circuit 22 d. Since the digital circuit 22 d is resetduring the safety time interval, the setting time of the functionalcircuit 22 may be effectively shortened.

FIG. 6 illustrates application of a control circuit 400 according to anembodiment. The control circuit 400 may be an embodiment of the controlcircuit 200 of FIG. 2. The foresaid functional circuit may be a phaselocked loop circuit. A phase locked loop circuit 44 in FIG. 6 may be apartial and simplified structure of a phase locked loop circuit. Thedigital circuit may be a digital frequency divider 44 d of the phaselocked loop circuit 44, and the analog circuit may be an analogfrequency divider 44 a of the phase locked loop circuit 44. Thedetermination circuit 220 may include a flip flop 420. The reset circuit210 may include a logic circuit 410. The flip flop 420 may include aclock terminal CK, an input terminal D and an output terminal Q. Theclock terminal CK may be coupled to a clock source and used to receive aclock signal Sck having a clock waveform. The input terminal D may beused to receive second data S2. The output terminal Q may be used tooutput first data S1 according to the second data S2 and the clocksignal Sck.

For example, the first data S1 may be updated and outputted according tothe second data S2 at the rising edge or falling edge of the clocksignal Sck. The logic circuit 410 may shift the first data S1 by a fixedvalue so as to update the second data S2. For example, if the shiftingoperation is a subtraction calculation, and the fixed value is one, theoperation of the logic circuit 410 may be represented as an equationS2=S1−1. The logic circuit 410 and the flip flop 420 may thus perform abackward counting operation. In other examples, the logic circuit 410and the flip flop 420 may perform another backward counting operation bysubtracting another subtrahend or a forward counting operation. Thelogic circuit 410 may include an input terminal i1, an output terminalo1 and another output terminal o2. The input terminal i1 may be coupledto the output terminal Q of the flip flop 420 and used to receive thefirst data S1. The output terminal o1 may be coupled to the inputterminal D of the flip flop 420 and used to output the second data S2.The output terminal o2 may be coupled to the output terminal of thereset circuit 210 to be coupled to the digital frequency divider 44 d toperform the reset operation or stop performing the reset operation. Whenthe first data S1 has reached a constant Ct1, the logic circuit 410 maystop performing the reset operation through the output terminal o2. Whenthe first data S1 has not yet reached the constant Ct1, the logiccircuit 410 may perform the reset operation through the output terminalo2. The constant Ct1 may be corresponding to the predetermined timeinterval T1. Stopping performing the reset operation may be stoppingtransmitting the at least one reset signal Sr to the digital frequencydivider 44 d or converting the reset signal Sr from an enabling level toa disabling level. Performing the reset operation may be as described inFIG. 3 to FIG. 5.

For example, if the constant Ct1 is zero, the fix value is one, and aninitial value of the first data S1 is 2000, when the logic circuit 410and the flip flop 420 perform a backward counting operation with thepulse of the clock signal Sck, the first data S1 may be graduallyupdated to be 1999, 1998, 1997, . . . , until the constant Ct1 (i.e. 0in this example) has reached. When the first data S1 has not reached theconstant Ct1, the logic circuit 410 may perform the reset operation tothe digital frequency divider 44 d as described in FIG. 3 to FIG. 5 bytransmitting at least one reset signal Sr. When the first data S1 hasreached the constant Ct1, the logic circuit 410 may stop performing thereset operation by stopping transmitting the at least one reset signalSr or converting the level of the reset signal Sr from an enabling levelto a disabling level. The initial value of the first data S1 and theconstant Ct1 may be set corresponding to the predetermined time intervalT1. Hence, the determination circuit 220 may determine whether thepredetermined time interval T1 has elapsed by counting.

As shown in FIG. 6, the control circuit 400 may further include anoperation voltage generation circuit 430 and a capacitor C1. Theoperation voltage generation circuit 430 may include an output terminalcoupled to the analog frequency divider 44 a. The capacitor C1 mayinclude a first terminal coupled to the output terminal of the operationvoltage generation circuit 430, and a second terminal. The phase lockedloop circuit 44 may further include an oscillation source VCO coupled tothe second terminal of the capacitor C1. The oscillation source VCO maybe (but not limited to) a voltage controlled oscillator. Thepredetermined time interval T1 may correspond to the time required for avoltage V1 of the first terminal of the capacitor C1 to reach a ratio ofa predetermined voltage. For example, when the analog frequency divider44 a stabilizes from an unstable state, the capacitor C1 may be chargedgradually, so the voltage V1 may increase. The time for the voltage V1to reach the ratio (e.g. 90%) of the predetermined voltage (e.g. amaximum value of the voltage V1) may correspond to the predeterminedtime interval T1. The foresaid predetermined voltage and the ratio maybe set according to the predetermined time interval T1.

According to an embodiment, as shown in FIG. 6, the operation voltagegeneration circuit 430 may include a bias voltage generator B1 and aresistor R1. The bias voltage generator B1 may include an outputterminal used for providing a bias voltage Vb where the bias voltage Vbis a stable value substantially. The resistor R1 may include a firstterminal coupled to the output terminal of the operation voltagegeneration circuit 430, and a second terminal coupled to the outputterminal of the bias voltage generator B1 for receiving the bias voltageVb.

For example, if the bias voltage generator B1 is a 1.5 volt battery, thebias voltage Vb may be 1.5 volts. The bias voltage Vb may charge thecapacitor C1 through the resistor R1. In the example of FIG. 6, thevoltage provided by the oscillation source VCO may have an oscillatingwaveform. The mean value of the voltage provided by the oscillationsource VCO to the second terminal of the capacitor C1 may be 0.5 volts.The voltages at the two terminals of the capacitor C1 may besubstantially equal initially, and then the voltage V1 may rise from 0.5volts to 1.5 volts when the capacitor C1 is charged. In this example,the maximum value of the voltage V1 may be 1.5 volts. Thus, it may bedefined that when the voltage V1 has reached a ratio (e.g. 90%) of 1.5volts, the predetermined time interval T1 has elapsed.

FIG. 7 illustrates application of a control circuit 500 according to anembodiment. The control circuit 500 may be an embodiment of the controlcircuit 200 of FIG. 2. The determination circuit 220 may be coupled tothe analog frequency divider 44 a to determine whether the predeterminedtime interval T1 has elapsed according to a tested voltage Vt of theanalog frequency divider 44 a. Like FIG. 6, FIG. 7 shows that the phaselocked loop circuit 44 may be an example of the functional circuit. Thephase locked loop circuit 44 in FIG. 7 may be a partial and simplifiedstructure of a phase locked loop circuit. The phase locked loop circuit44 may include the digital frequency divider 44 d, the analog frequencydivider 44 a and the oscillation source VCO. The control circuit 500 mayinclude an operation voltage generation circuit 530 and the capacitorC1. The operation voltage generation circuit 530 may include an outputterminal coupled to the input terminal of the analog frequency divider44 a. The input terminal of the analog frequency divider 44 a mayreceive the tested voltage Vt. The first terminal of the capacitor C1may be coupled to the output terminal of the operation voltagegeneration circuit 530. The predetermined time interval T1 maycorrespond to a time required for a voltage of the first terminal of thecapacitor C1 to reach a ratio of a predetermined voltage.

In the example of FIG. 7, the voltage of the first terminal of thecapacitor C1 may correspond to the tested voltage Vt. The foresaidpredetermined voltage may be a maximum value of the tested voltage Vt.The foresaid ratio may be 90% or another suitable ratio. The secondterminal of the capacitor C1 may be coupled to the oscillation sourceVCO. Like the operation voltage generation circuit 430 in FIG. 6, theoperation voltage generation circuit 530 may include a bias voltagegenerator B11 and a resistor R11. The bias voltage generator B11 mayinclude an output terminal used for providing a bias voltage Vbb wherethe bias voltage Vbb is a stable value substantially. The resistor R11may include a first terminal coupled to the output terminal of theoperation voltage generation circuit 530, and a second terminal coupledto the output terminal of the bias voltage generator B11 to receive thebias voltage Vbb.

In the control circuit 500, the determination circuit 220 may include adetection circuit 512. The detection circuit 512 may include a firstterminal, a second terminal and a third terminal. The first terminal maybe coupled to the second terminal of the resistor R11 and used toreceive the bias voltage Vbb, and the third terminal may be coupled to areference voltage terminal Vr. The reset circuit 210 may include acomparator 514. The comparator 514 may include a first terminal coupledto the output terminal of the bias voltage generator B11 to receive thebias voltage Vbb, a second terminal coupled to the second terminal ofthe detection circuit 512 to receive an operation voltage Vk. Theoperation voltage Vk may correspond to the tested voltage Vt asdescribed below. The comparator 514 may further include an outputterminal coupled to the output terminal of the reset circuit 210 to stopthe reset operation when the operation voltage Vk reaches the biasvoltage Vbb substantially. For example, the reset operation may bestopped by stopping transmitting the at least one the reset signal Sr orconverting the reset signal Sr from an enabling level to a disablinglevel. The predetermined time interval T1 may correspond to the timerequired for the operation voltage Vk to reach the bias voltage Vbbsubstantially.

According to an embodiment, the detection circuit 512 may include aresistor R52 and a capacitor C52. The resistor R52 may include a firstterminal coupled to the first terminal of the detection circuit 512, anda second terminal coupled to the second terminal of the detectioncircuit 512. The capacitor C52 may include a first terminal coupled tothe second terminal of the resistor R52, and a second terminal coupledto the third terminal of the detection circuit 512.

Because the bias voltage Vbb (e.g. 1.5 volts) provide by the biasvoltage generator B11 may be a stable value substantially, if the meanvalue of the voltage (e.g. 0.5 volts) provided to the second terminal ofthe capacitor C1 by the oscillation source VCO is also a stable value,the tested voltage Vt may increase gradually when the capacitor C1 ischarged. For example, the tested voltage Vt may increase from 0.5 voltsto 1.5 volts gradually. The product of capacitance of the capacitor C1and resistance of the resistor R11 may be adjusted to equal the productof capacitance of the capacitor C52 and resistance of the resistor R52substantially. Thus, a voltage Vk1 at a node between the resistor R52and the capacitor C52 may approach the bias voltage Vbb. For example,the voltage Vk1 may increase from 0 volts to 1.5 volts gradually. Byconfiguring the electric circuit, the voltage Vk1 may vary with thetested voltage Vt, and the operation voltage Vk may vary with thevoltage Vk1, so the operation voltage Vk may vary with the testedvoltage Vt. The abovementioned voltages are merely provided as examplesinstead of limiting the scope of the present invention. In FIG. 7, thevoltage Vk1 may equal the operation voltage Vk substantially since thetwo voltages are at one same node. However, as shown in FIG. 8, thevoltage Vk1 and the operation voltage Vk may be at different nodesaccording to another embodiment.

FIG. 8 illustrates a partial circuit of the control circuit 500 of FIG.7 according to another embodiment. In FIG. 8, the determination circuit220 may further include an offset circuit 612 coupled between the secondterminal of the detection circuit 512 and the second terminal of thecomparator 514 so as to provide an offset voltage Vs. A level of thevoltage Vk1 at the second terminal of the detection circuit 512 maytherefore be adjusted. For example, the level of the voltage Vk1 may beheightened or lowered. The operation voltage Vk may equal a sum of thevoltage Vk1 at the second terminal of the detection circuit 512 and theoffset voltage Vs. Because the operation voltage Vk may be higher thanthe voltage Vk1, and a difference between the operation voltage Vk andthe voltage Vk1 may be the offset voltage Vs, the operation voltage Vkmay reach the bias voltage Vbb to trigger the comparator 514 to adjustthe reset signal Sr when the voltage Vk1 is increased to approach thebias voltage Vbb but has not yet reached the bias voltage Vbb. Theoffset circuit 612 may be optionally used for circuit designrequirements.

As shown in FIG. 8, the offset circuit 612 may include a transistor T1.The transistor T1 may include a first terminal coupled to the secondterminal of the comparator 514, a second terminal coupled to a referencevoltage terminal Vr1, and a control terminal coupled the second terminalof the detection circuit 512. The first terminal of the transistor T1may receive a current provided by a current source CS1 so as to have thetransistor T1 operate in an saturation region, and have a voltagedifference between the control terminal and the first terminal of thetransistor T1 equal the offset voltage Vs. This circuit structure may bean example, and other suitable offset circuits may be used according toother embodiments.

FIG. 9 illustrates application of a control circuit 700 according toanother embodiment. The control circuit 700 may be an embodiment of thecontrol circuit 200 of FIG. 2. The control circuit 700 may include areset circuit 710 and a determination circuit 720. The reset circuit 710may perform or stop performing a reset operation by using the resetsignal Sr. The determination circuit 720 may include a detection circuit722. The detection circuit 722 may include an input terminal and anoutput terminal, the input terminal may be coupled to the outputterminal of the analog frequency divider 44 a for receiving a testedvoltage Vto, and the output terminal may be used to output a controlsignal Sc. The detection circuit 722 may determine that the analogfrequency divider 44 a has stabilized, and the output terminal of thedetection circuit 722 may output the control signal Sc when the testedvoltage Vto has reached a threshold. The threshold may be a ratio of apredetermined voltage (e.g. a maximum value of the tested voltage Vto)or a specific threshold voltage. The threshold may correspond to thestabilization of the analog frequency divider 44 a, and thepredetermined time interval T1 may be the time required for the analogfrequency divider 44 a to stabilize. The reset circuit 710 may include acontrol terminal coupled to the output terminal of the detection circuit722 to receive the control signal Sc, and an output terminal coupled tothe digital frequency divider 44 d to stop performing the resetoperation according to the control signal Sc. Thus, the determinationcircuit 720 may determine whether the predetermined time interval T1 haselapsed according to the tested voltage Vto at the output terminal ofthe analog frequency divider 44 a, and the predetermined time intervalT1 may correspond to a required time for the tested voltage Vto to reachthe threshold substantially.

FIG. 10 illustrates application of a control circuit 800 according toanother embodiment. In FIG. 10, more functional blocks of a phase lockedloop circuit are illustrated. The phase locked loop circuit 84 in FIG.10 may include a phase frequency detector PFD, a low pass filter LF, aninverter INV, an oscillation source VCO, the analog frequency divider 44a, and digital frequency dividers 44 d 1 and 44 d 2. According to anembodiment, the analog frequency divider 44 a may be a high speedprescaler, and the digital frequency dividers 44 d 1 and 44 d 2 may below speed frequency dividers. The phase frequency detector PFD maygenerate a phase difference Pe and output the phase difference Pe to thelow pass filter LF according to a reference signal Sref and a feedbacksignal Sfb. The low pass filter LF may generate a filtered signal SLFand output the filtered signal SLF to the oscillation source VCOaccording to the phase difference Pe, and the oscillation source VCO mayoutput the oscillation signal S_(osc) according to the filtered signalSLF. The analog frequency divider 44 a may output a frequency dividedsignal S81 to the digital frequency dividers 44 d 1 and 44 d 2accordingly. The digital frequency divider 44 d 1 may output a frequencydivided signal S82 to the inverter INV and the digital frequency divider44 d 2, and the digital frequency divider 44 d 2 may output thefrequency divided signal S83 to the analog frequency divider 44 aaccordingly. The inverter INV may output the feedback signal Sfbaccording to the frequency divided signal S82. The functional blocks ofthe phase locked loop circuit 84 may form a negative feedback structure.According to an embodiment, the phase frequency detector PFD may includea charge pump.

As shown in FIG. 10, the phase locked loop circuit 84 may furtherinclude at least one switch. A switch SW1 may be coupled between theoutput terminal of the analog frequency divider 44 a and the inputterminal of the digital frequency divider 44 d 1. A switch SW2 may becoupled between the output terminal of the analog frequency divider 44 aand the input terminal of the digital frequency divider 44 d 2. A switchSW3 may be coupled between the output terminal of the digital frequencydivider 44 d 1 and the input terminal of the inverter INV. As shown inFIG. 10, the switch SW3 may be coupled among the inverter INV and thedigital frequency dividers 44 d 1 and 44 d 2, and placed on the pathfrom the digital frequency dividers 44 d 1 and 44 d 2 to the oscillationsource VCO. The control circuit 800 may be similar to the controlcircuit 200, so the details are not described repeatedly. When the resetcircuit of the control circuit 800 performs a reset operation, at leastone of the switches SW1 to SW3 may be turned off. When the reset circuitstops performing the reset operation, the switches SW1 to SW3 may beturned on by controlling the reset signal Sr to correctly reset one orboth of the digital frequency dividers 44 d 1 and 44 d 2 after theanalog frequency divider 44 a has stabilized for a safety time interval,for example, after the predetermined time interval T1 has elapsed. Thepredetermined time interval T1 may be set according to the time requiredfor the analog frequency divider 44 a to stabilize. The determinationcircuit of the control circuit 800 may determine whether thepredetermined time interval has elapsed by counting or measuring atested voltage at the analog frequency divider. In FIG. 10, theoperation voltage generation circuit 830 may be similar to the foresaidoperation voltage generation circuits 430 and 530, so it is notrepeated.

In summary, the reset circuit 210 of the control circuit 200 of FIG. 2may perform a reset operation to the digital circuit 22 d of thefunctional circuit 22, and the determination circuit 220 may determinewhether the analog circuit 22 a of the functional circuit 22 hasstabilized. The reset circuit 210 may stop performing the resetoperation after that the analog circuit 22 a has stabilized and then asafety time interval has elapsed. During the safety time interval, atleast one reset signal Sr may be used to reset the digital circuit 22 d.The determination circuit 220 may determine whether the analog circuit22 a has stabilized by determining whether the predetermined timeinterval T1 has elapsed by counting using a flip flop (e.g. FIG. 6), byobserving the tested voltage Vt at the input terminal of the analogfrequency divider 44 a (e.g. FIG. 7), or by observing the tested voltageVto at the output terminal of the analog frequency divider 44 a (e.g.FIG. 9). The foresaid reset operation may be resetting the digitalcircuit directly using a reset signal or by controlling a switch of afunctional circuit. By means of control circuits provided by theembodiments, a reset operation may be performed constantly till ananalog circuit has stabilized, and then the reset operation may bestopped. Therefore, a setting time required for initializing afunctional circuit may be effectively shortened, and the efficiency ofthe control circuit may be improved.

Those skilled in the art will readily observe that numerousmodifications and alterations of the device and method may be made whileretaining the teachings of the invention. Accordingly, the abovedisclosure should be construed as limited only by the metes and boundsof the appended claims.

What is claimed is:
 1. A control circuit, comprising: a reset circuitcoupled to a digital frequency divider of a phase locked loop circuitand configured to perform a reset operation wherein the phase lockedloop circuit further comprises an analog frequency divider coupled tothe digital frequency divider, and a first predetermined time intervalcorresponds to a time required for the analog frequency divider tostabilize; and a determination circuit coupled to the reset circuit andthe analog frequency divider and configured to determine whether thefirst predetermined time interval has elapsed according to a testedvoltage at the analog frequency divider so as to control the resetcircuit to stop performing the reset operation when the firstpredetermined time interval has elapsed.
 2. The control circuit of claim1, wherein: the phase locked loop circuit further comprises anoscillation source; the control circuit further comprises: an operationvoltage generation circuit, comprising: an output terminal coupled to aninput terminal of the analog frequency divider; and a first capacitor,comprising: a first terminal coupled to the output terminal of theoperation voltage generation circuit; and a second terminal coupled tothe oscillation source; the reset circuit comprises: an output terminalconfigured to perform the reset operation or stop performing the resetoperation; the first predetermined time interval corresponds to a timerequired for a voltage of the first terminal of the first capacitor toreach a ratio of a predetermined voltage; the analog frequency divideris configured to receive the tested voltage; and the voltage of thefirst terminal of the first capacitor corresponds to the tested voltage.3. The control circuit of claim 2, wherein: the operation voltagegeneration circuit further comprises: a bias voltage generator,comprising: an output terminal configured to provide a bias voltage,wherein the bias voltage is a stable value substantially; and a firstresistor, comprising: a first terminal coupled to the output terminal ofthe operation voltage generation circuit; and a second terminal coupledto the output terminal of the bias voltage generator and configured toreceive the bias voltage; the determination circuit comprises adetection circuit comprising: a first terminal coupled to the secondterminal of the first resistor and configured to receive the biasvoltage; a second terminal; and a third terminal coupled to a firstreference voltage terminal; the reset circuit further comprises: acomparator comprising: a first terminal coupled to the output terminalof the bias voltage generator and configured to receive the biasvoltage; a second terminal coupled to the second terminal of thedetection circuit and configured to receive a third operation voltagecorresponding to the tested voltage; and an output terminal coupled tothe output terminal of the reset circuit and configured to stop thereset operation when the third operation voltage reaches the biasvoltage substantially; and the first predetermined time intervalcorresponds to a time required for the third operation voltage to reachthe bias voltage substantially.
 4. The control circuit of claim 3,wherein: the determination circuit further comprises: an offset circuitcoupled between the second terminal of the detection circuit and thesecond terminal of the comparator and configured to provide an offsetvoltage so as to adjust a voltage level at the second terminal of thedetection circuit; and the third operation voltage equals a sum of avoltage at the second terminal of the detection circuit and the offsetvoltage.
 5. The control circuit of claim 4, wherein the offset circuitcomprises a transistor comprising: a first terminal coupled to thesecond terminal of the comparator; a second terminal coupled to a secondreference voltage terminal; and a control terminal coupled the secondterminal of the detection circuit.
 6. The control circuit of claim 3,wherein the detection circuit comprises: a second resistor, comprising:a first terminal coupled to the first terminal of the detection circuit;and a second terminal coupled to the second terminal of the detectioncircuit; and a second capacitor, comprising: a first terminal coupled tothe second terminal of the second resistor; a second terminal coupled tothe third terminal of the detection circuit.
 7. The control circuit ofclaim 6, wherein product of capacitance of the first capacitor andresistance of the first resistor equals product of capacitance of thesecond capacitor and resistance of the second resistor substantially. 8.The control circuit of claim 1, wherein the determination circuitcomprises a detection circuit comprising: an input terminal coupled toan output terminal of the analog frequency divider and configured toreceive the tested voltage; and an output terminal configured to outputa control signal; the reset circuit comprises: a control terminalcoupled to the output terminal of the detection circuit and configuredto receive the control signal; and an output terminal coupled to thedigital frequency divider and configured to stop performing the resetoperation according to the control signal; the detection circuitdetermines that the analog frequency divider has stabilized, and theoutput terminal of the detection circuit outputs the control signal whenthe tested voltage reaches a threshold; and the first predetermined timeinterval corresponds to a time required for the tested voltage to reachthe threshold substantially.
 9. A control circuit, comprising: a resetcircuit coupled to a digital frequency divider of a phase locked loopcircuit and configured to perform a reset operation wherein the phaselocked loop circuit further comprises an analog frequency dividercoupled to the digital frequency divider, and a first predetermined timeinterval corresponds to a time required for the analog frequency dividerto stabilize; a determination circuit coupled to the reset circuit andconfigured to determine whether a first predetermined time interval haselapsed so as to control the reset circuit to stop performing the resetoperation when the first predetermined time interval has elapsed; and atleast one switch coupled to the digital frequency divider; whereinperforming the reset operation comprises turning off the at least oneswitch by the reset circuit, and stopping performing the reset operationcomprises turning on the at least one switch by the reset circuit. 10.The control circuit of claim 9, wherein the at least one switch iscoupled between the digital frequency divider and the analog frequencydivider.
 11. The control circuit of claim 9, wherein the phase lockedloop circuit further comprises an oscillation source, and the at leastone switch is coupled between the digital frequency divider and theoscillation source.
 12. A control circuit, comprising: a reset circuitcoupled to a digital circuit of a functional circuit and configured toperform a reset operation to the digital circuit wherein the functionalcircuit further comprises an analog circuit coupled to the digitalcircuit, and a first predetermined time interval corresponds to a timerequired for the analog circuit to stabilize; and a determinationcircuit coupled to the reset circuit and the analog circuit andconfigured to determine whether the first predetermined time intervalhas elapsed according to a tested voltage at the analog circuit so as tocontrol the reset circuit to stop performing the reset operation whenthe first predetermined time interval has elapsed.